TSTP Solution File: SYN374+1 by SRASS---0.1

View Problem - Process Solution 
%------------------------------------------------------------------------------
% File     : SRASS---0.1
% Problem  : SYN374+1 : TPTP v5.0.0. Released v2.0.0.
% Transfm  : none
% Format   : tptp
% Command  : SRASS -q2 -a 0 10 10 10 -i3 -n60 %s

% Computer : art05.cs.miami.edu
% Model    : i686 i686
% CPU      : Intel(R) Pentium(R) 4 CPU 2.80GHz @ 2793MHz
% Memory   : 2018MB
% OS       : Linux 2.6.26.8-57.fc8
% CPULimit : 300s
% DateTime : Thu Dec 30 09:26:43 EST 2010

% Result   : Theorem 0.88s
% Output   : Solution 0.88s
% Verified : 
% SZS Type : None (Parsing solution fails)
% Syntax   : Number of formulae    : 0

% Comments : 
%------------------------------------------------------------------------------
%----ERROR: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% Reading problem from /tmp/SystemOnTPTP24387/SYN374+1.tptp
% Adding relevance values
% Extracting the conjecture
% Sorting axioms by relevance
% Looking for THM       ... found
% SZS status THM for /tmp/SystemOnTPTP24387/SYN374+1.tptp
% SZS output start Solution for /tmp/SystemOnTPTP24387/SYN374+1.tptp
% TreeLimitedRun: ----------------------------------------------------------
% TreeLimitedRun: /home/graph/tptp/Systems/EP---1.2/eproof --print-statistics -xAuto -tAuto --cpu-limit=60 --proof-time-unlimited --memory-limit=Auto --tstp-in --tstp-out /tmp/SRASS.s.p 
% TreeLimitedRun: CPU time limit is 60s
% TreeLimitedRun: WC  time limit is 120s
% TreeLimitedRun: PID is 24483
% TreeLimitedRun: ----------------------------------------------------------
% PrfWatch: 0.00 CPU 0.02 WC
% # Preprocessing time   : 0.010 s
% # Problem is unsatisfiable (or provable), constructing proof object
% # SZS status Theorem
% # SZS output start CNFRefutation.
% fof(1, conjecture,(?[X1]:![X2]:(big_p(X1)<=>big_p(X2))<=>(?[X1]:big_p(X1)<=>![X2]:big_p(X2))),file('/tmp/SRASS.s.p', x2125)).
% fof(2, negated_conjecture,~((?[X1]:![X2]:(big_p(X1)<=>big_p(X2))<=>(?[X1]:big_p(X1)<=>![X2]:big_p(X2)))),inference(assume_negation,[status(cth)],[1])).
% fof(3, negated_conjecture,((![X1]:?[X2]:((~(big_p(X1))|~(big_p(X2)))&(big_p(X1)|big_p(X2)))|((![X1]:~(big_p(X1))|?[X2]:~(big_p(X2)))&(?[X1]:big_p(X1)|![X2]:big_p(X2))))&(?[X1]:![X2]:((~(big_p(X1))|big_p(X2))&(~(big_p(X2))|big_p(X1)))|((![X1]:~(big_p(X1))|![X2]:big_p(X2))&(?[X2]:~(big_p(X2))|?[X1]:big_p(X1))))),inference(fof_nnf,[status(thm)],[2])).
% fof(4, negated_conjecture,((![X3]:?[X4]:((~(big_p(X3))|~(big_p(X4)))&(big_p(X3)|big_p(X4)))|((![X5]:~(big_p(X5))|?[X6]:~(big_p(X6)))&(?[X7]:big_p(X7)|![X8]:big_p(X8))))&(?[X9]:![X10]:((~(big_p(X9))|big_p(X10))&(~(big_p(X10))|big_p(X9)))|((![X11]:~(big_p(X11))|![X12]:big_p(X12))&(?[X13]:~(big_p(X13))|?[X14]:big_p(X14))))),inference(variable_rename,[status(thm)],[3])).
% fof(5, negated_conjecture,((![X3]:((~(big_p(X3))|~(big_p(esk1_1(X3))))&(big_p(X3)|big_p(esk1_1(X3))))|((![X5]:~(big_p(X5))|~(big_p(esk2_0)))&(big_p(esk3_0)|![X8]:big_p(X8))))&(![X10]:((~(big_p(esk4_0))|big_p(X10))&(~(big_p(X10))|big_p(esk4_0)))|((![X11]:~(big_p(X11))|![X12]:big_p(X12))&(~(big_p(esk5_0))|big_p(esk6_0))))),inference(skolemize,[status(esa)],[4])).
% fof(6, negated_conjecture,![X3]:![X5]:![X8]:![X10]:![X11]:![X12]:((((big_p(X12)|~(big_p(X11)))&(~(big_p(esk5_0))|big_p(esk6_0)))|((~(big_p(esk4_0))|big_p(X10))&(~(big_p(X10))|big_p(esk4_0))))&(((big_p(X8)|big_p(esk3_0))&(~(big_p(X5))|~(big_p(esk2_0))))|((~(big_p(X3))|~(big_p(esk1_1(X3))))&(big_p(X3)|big_p(esk1_1(X3)))))),inference(shift_quantors,[status(thm)],[5])).
% fof(7, negated_conjecture,![X3]:![X5]:![X8]:![X10]:![X11]:![X12]:(((((~(big_p(esk4_0))|big_p(X10))|(big_p(X12)|~(big_p(X11))))&((~(big_p(X10))|big_p(esk4_0))|(big_p(X12)|~(big_p(X11)))))&(((~(big_p(esk4_0))|big_p(X10))|(~(big_p(esk5_0))|big_p(esk6_0)))&((~(big_p(X10))|big_p(esk4_0))|(~(big_p(esk5_0))|big_p(esk6_0)))))&((((~(big_p(X3))|~(big_p(esk1_1(X3))))|(big_p(X8)|big_p(esk3_0)))&((big_p(X3)|big_p(esk1_1(X3)))|(big_p(X8)|big_p(esk3_0))))&(((~(big_p(X3))|~(big_p(esk1_1(X3))))|(~(big_p(X5))|~(big_p(esk2_0))))&((big_p(X3)|big_p(esk1_1(X3)))|(~(big_p(X5))|~(big_p(esk2_0))))))),inference(distribute,[status(thm)],[6])).
% cnf(9,negated_conjecture,(~big_p(esk2_0)|~big_p(X1)|~big_p(esk1_1(X2))|~big_p(X2)),inference(split_conjunct,[status(thm)],[7])).
% cnf(10,negated_conjecture,(big_p(esk3_0)|big_p(X1)|big_p(esk1_1(X2))|big_p(X2)),inference(split_conjunct,[status(thm)],[7])).
% cnf(14,negated_conjecture,(big_p(X2)|big_p(esk4_0)|~big_p(X1)|~big_p(X3)),inference(split_conjunct,[status(thm)],[7])).
% cnf(15,negated_conjecture,(big_p(X2)|big_p(X3)|~big_p(X1)|~big_p(esk4_0)),inference(split_conjunct,[status(thm)],[7])).
% fof(16, plain,(~(epred1_0)<=>![X2]:((~(big_p(esk1_1(X2)))|~(big_p(esk2_0)))|~(big_p(X2)))),introduced(definition),['split']).
% cnf(17,plain,(epred1_0|~big_p(X2)|~big_p(esk2_0)|~big_p(esk1_1(X2))),inference(split_equiv,[status(thm)],[16])).
% fof(18, plain,(~(epred2_0)<=>![X1]:~(big_p(X1))),introduced(definition),['split']).
% cnf(19,plain,(epred2_0|~big_p(X1)),inference(split_equiv,[status(thm)],[18])).
% cnf(20,negated_conjecture,(~epred2_0|~epred1_0),inference(apply_def,[status(esa)],[inference(apply_def,[status(esa)],[9,16,theory(equality)]),18,theory(equality)]),['split']).
% cnf(24,negated_conjecture,(epred2_0|big_p(esk3_0)|big_p(X1)|big_p(X2)),inference(spm,[status(thm)],[19,10,theory(equality)])).
% cnf(31,negated_conjecture,(epred1_0|big_p(esk1_1(X2))|big_p(esk3_0)|big_p(X2)|~big_p(esk2_0)|~big_p(X1)),inference(spm,[status(thm)],[17,10,theory(equality)])).
% cnf(33,negated_conjecture,(epred2_0|big_p(esk3_0)|big_p(X1)),inference(csr,[status(thm)],[24,19])).
% cnf(34,negated_conjecture,(epred2_0|big_p(esk3_0)),inference(csr,[status(thm)],[33,19])).
% cnf(35,negated_conjecture,(epred2_0),inference(csr,[status(thm)],[34,19])).
% cnf(36,negated_conjecture,($false|~epred1_0),inference(rw,[status(thm)],[20,35,theory(equality)])).
% cnf(37,negated_conjecture,(~epred1_0),inference(cn,[status(thm)],[36,theory(equality)])).
% cnf(39,negated_conjecture,(big_p(esk1_1(X2))|big_p(esk3_0)|big_p(X2)|~big_p(esk2_0)|~big_p(X1)),inference(sr,[status(thm)],[31,37,theory(equality)])).
% cnf(40,negated_conjecture,(big_p(esk1_1(X2))|big_p(esk3_0)|big_p(X2)|~big_p(esk2_0)),inference(csr,[status(thm)],[39,10])).
% cnf(41,negated_conjecture,(big_p(esk1_1(X2))|big_p(esk3_0)|big_p(X2)),inference(csr,[status(thm)],[40,10])).
% cnf(42,negated_conjecture,(big_p(esk4_0)|big_p(X1)|big_p(esk3_0)|big_p(X2)|~big_p(X3)),inference(spm,[status(thm)],[14,41,theory(equality)])).
% cnf(48,negated_conjecture,(big_p(esk4_0)|big_p(esk3_0)|big_p(X1)|~big_p(X3)),inference(csr,[status(thm)],[42,14])).
% cnf(49,negated_conjecture,(big_p(esk4_0)|big_p(X1)|~big_p(X3)),inference(csr,[status(thm)],[48,14])).
% cnf(50,negated_conjecture,(big_p(esk4_0)|big_p(X1)|big_p(esk3_0)|big_p(X2)),inference(spm,[status(thm)],[49,41,theory(equality)])).
% cnf(51,negated_conjecture,(big_p(esk4_0)|big_p(esk3_0)|big_p(X1)),inference(csr,[status(thm)],[50,49])).
% cnf(52,negated_conjecture,(big_p(esk4_0)|big_p(X1)),inference(csr,[status(thm)],[51,49])).
% cnf(53,negated_conjecture,(big_p(esk4_0)),inference(ef,[status(thm)],[52,theory(equality)])).
% cnf(62,negated_conjecture,(big_p(X1)|big_p(X2)|$false|~big_p(X3)),inference(rw,[status(thm)],[15,53,theory(equality)])).
% cnf(63,negated_conjecture,(big_p(X1)|big_p(X2)|~big_p(X3)),inference(cn,[status(thm)],[62,theory(equality)])).
% cnf(64,negated_conjecture,(big_p(X1)|big_p(X2)),inference(spm,[status(thm)],[63,53,theory(equality)])).
% cnf(66,negated_conjecture,(big_p(X3)),inference(ef,[status(thm)],[64,theory(equality)])).
% cnf(72,negated_conjecture,(epred1_0|$false|~big_p(esk2_0)|~big_p(X1)),inference(rw,[status(thm)],[17,66,theory(equality)])).
% cnf(73,negated_conjecture,(epred1_0|$false|$false|~big_p(X1)),inference(rw,[status(thm)],[72,66,theory(equality)])).
% cnf(74,negated_conjecture,(epred1_0|$false|$false|$false),inference(rw,[status(thm)],[73,66,theory(equality)])).
% cnf(75,negated_conjecture,(epred1_0),inference(cn,[status(thm)],[74,theory(equality)])).
% cnf(76,negated_conjecture,($false),inference(sr,[status(thm)],[75,37,theory(equality)])).
% cnf(77,negated_conjecture,($false),76,['proof']).
% # SZS output end CNFRefutation
% # Processed clauses                : 29
% # ...of these trivial              : 0
% # ...subsumed                      : 1
% # ...remaining for further processing: 28
% # Other redundant clauses eliminated : 0
% # Clauses deleted for lack of memory : 0
% # Backward-subsumed                : 11
% # Backward-rewritten               : 5
% # Generated clauses                : 34
% # ...of the previous two non-trivial : 32
% # Contextual simplify-reflections  : 11
% # Paramodulations                  : 25
% # Factorizations                   : 6
% # Equation resolutions             : 0
% # Current number of processed clauses: 3
% #    Positive orientable unit clauses: 2
% #    Positive unorientable unit clauses: 0
% #    Negative unit clauses         : 1
% #    Non-unit-clauses              : 0
% # Current number of unprocessed clauses: 0
% # ...number of literals in the above : 0
% # Clause-clause subsumption calls (NU) : 54
% # Rec. Clause-clause subsumption calls : 32
% # Unit Clause-clause subsumption calls : 8
% # Rewrite failures with RHS unbound: 0
% # Indexed BW rewrite attempts      : 7
% # Indexed BW rewrite successes     : 7
% # Backwards rewriting index:     4 leaves,   1.00+/-0.000 terms/leaf
% # Paramod-from index:            2 leaves,   1.00+/-0.000 terms/leaf
% # Paramod-into index:            3 leaves,   1.00+/-0.000 terms/leaf
% # -------------------------------------------------
% # User time            : 0.010 s
% # System time          : 0.003 s
% # Total time           : 0.013 s
% # Maximum resident set size: 0 pages
% PrfWatch: 0.09 CPU 0.17 WC
% FINAL PrfWatch: 0.09 CPU 0.17 WC
% SZS output end Solution for /tmp/SystemOnTPTP24387/SYN374+1.tptp
% 
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